We apply the cantilever deflection technique to measure stress in nm thin BaTiO₃ and SrTiO₃ films during pulsed laser deposition on a Pt(001) single crystal cantilever substrate. We find a compressive film stress of -4.2 GPa for BaTiO₃ on Pt(001) (misfit = -2.3%), whereas the deposition of SrTiO₃ (misfit = +0.4%) induces a tensile stress of +1.5 GPa. The stress measurements are augmented by in situ low energy electron diffraction experiments which indicate an epitaxial order of the films. We apply continuum elasticity to calculate film stress. We conclude that sign and magnitude of the measured stress are due to the epitaxial misfit between film and substrate, which is -2.3% and +0.4% for BaTiO₃ and SrTiO₃, respectively. We identify that in addition to misfit also the oxygen partial pressure during PLD film growth influences film stress. PLD growth in an oxygen-free environment leads to factor of two increased tensile stress in SrTiO₃ on Pt(001) as compared to growth at p_O2=10⁻⁴ mbar. The role of film stoichiometry for film stress is discussed.